Sound Wave in a sentence
Synonym: vibration.
Meaning: A wave of pressure that travels through air or another medium, producing sound.
(1) The sound wave fluctuated sinusoidally.
(2) The sound wave was distorted by the wind.
(3) The sound wave has a frequency of 20 kHz.
(4) The wave number of this sound wave is 50.
(5) The sound wave caused the ground to shake.
(6) The wave number of this sound wave is 100.
(7) The frequency of the sound wave is 440 Hz.
(8) The sound wave produced a beautiful melody.
(9) The sound wave caused the glass to shatter.
(10) The sound wave resonated with the audience.
Sound Wave sentence
(11) The amplitude of a sound wave can oscillate.
(12) The sound wave created a soothing atmosphere.
(13) The sound wave was amplified by the speakers.
(14) The matter in a sound wave can produce sound.
(15) The sound wave was captured by the microphone.
(16) The MSB of a sound wave determines its volume.
(17) The sound wave from the thunder was deafening.
(18) The sound wave from the music filled the room.
(19) The sound wave was so loud that it startled me.
(20) The sound wave was absorbed by the soft carpet.
Sound Wave make sentence
(21) The sound wave has a frequency of 20 kilohertz.
(22) The mean frequency of the sound wave is 500 Hz.
(23) The sound wave was analyzed using a spectrogram.
(24) The sound wave from the explosion was deafening.
(25) The sound wave was amplified by the sound system.
(26) The massless sound wave traveled through the air.
(27) The sound wave is isolable from background noise.
(28) The wave front of the sound wave hit my eardrums.
(29) The sound wave was measured using a decibel meter.
(30) The sound wave was modulated to carry information.
Sentence of sound wave
(31) The sound wave oscillates at a specific frequency.
(32) The sound wave moved sinusoidally through the air.
(33) The harmonic of a sound wave determines its pitch.
(34) The sound wave from the thunder shook the windows.
(35) The sound wave carried the message across the room.
(36) The sound wave was too high-pitched for me to hear.
(37) The sound wave was oscillating at a high frequency.
(38) The output method for this speaker is a sound wave.
(39) The sound wave from the speaker was loud and clear.
(40) The nominal frequency of the sound wave was 440 Hz.
Sound Wave meaningful sentence
(41) The frequency of the sound wave oscillated rapidly.
(42) The sound wave travels sinusoidally through the air.
(43) I could see the sound wave ripple through the water.
(44) The sound wave was produced by a musical instrument.
(45) The sound wave was recorded on a digital audio file.
(46) The wavelength of a sound wave determines its pitch.
(47) The sonar device emitted a low-frequency sound wave.
(48) The temporal frequency of a sound wave is its pitch.
(49) The wave number of a sound wave determines its pitch.
(50) The sound wave reverberated through the concert hall.
Sound Wave sentence examples
(51) The frequency of the sound wave is measured in hertz.
(52) The sonar device emitted a high-frequency sound wave.
(53) The kilocycles of the sound wave determine its pitch.
(54) The sound wave is isolable from the background noise.
(55) The field strength of a sound wave affects its volume.
(56) The nominal frequency of the sound wave was 440 hertz.
(57) The displacement of a sound wave affects its frequency.
(58) The amplitude of the sound wave increases sinusoidally.
(59) The sound wave was reflected off the walls of the room.
(60) The frequency of the sound wave increased sinusoidally.
Sentence with sound wave
(61) The sound wave propagated sinusoidally through the air.
(62) The sound wave from the guitar filled the concert hall.
(63) The ellipticity of a sound wave can determine its pitch.
(64) The sound wave from the explosion shattered the windows.
(65) Antinodes are points of maximum pressure in a sound wave.
(66) The amplitude of the sound wave was measured in decibels.
(67) The waveshape of the sound wave determines its frequency.
(68) A formula can help us find the frequency of a sound wave.
(69) I could feel the vibrations of the sound wave in my chest.
(70) The sound wave was transmitted through the telephone line.
Use sound wave in a sentence
(71) The energy dissipated in the reflection of the sound wave.
(72) The sound wave was quantised to fit into a digital format.
(73) The sound wave was quantised to make it easier to process.
(74) The amplitude of a sound wave can be adjusted sinusoidally.
(75) The sound wave was too low-frequency for my ears to detect.
(76) The sound wave was used to communicate over long distances.
(77) The periodic wave of a sound wave determines its frequency.
(78) The angular frequency of a sound wave determines its pitch.
(79) The sound wave traveled through the air and reached my ears.
(80) The sound wave traveled at a speed of 343 meters per second.
Sentence using sound wave
(81) The secondary wave traveled through the air as a sound wave.
(82) The antinode is a point of minimum pressure in a sound wave.
(83) The pulse amplitude of the sound wave determined its volume.
(84) The sound wave graph showed a flat line, indicating silence.
(85) The absolute-scale frequency of the sound wave is 440 hertz.
(86) The pulse amplitude of the sound wave determines its volume.
(87) The temporal frequency of a sound wave determines its pitch.
(88) The formation of a sound wave can be heard by the human ear.
(89) The squiggly line on the sound wave graph shows a loud noise.
(90) The collision between the two particles created a sound wave.
Sound Wave example sentence
(91) The angular frequency of the sound wave determined its pitch.
(92) The sound wave traveled through the air and reached our ears.
(93) The sound wave from the explosion shattered the glass windows.
(94) The sound wave from the speaker was too loud for the audience.
(95) The antinode is a point of maximum compression in a sound wave.
(96) The antinode is a point of maximum rarefaction in a sound wave.
(97) The fundamental frequency of a sound wave determines its pitch.
(98) The kilocycles of the sound wave can be adjusted using a mixer.
(99) The wave length of a sound wave determines its perceived pitch.
(100) Trace along the path of a sound wave to understand how we hear.
Sentence with word sound wave
(101) The piezoelectric element generated a high-frequency sound wave.
(102) The amplitude of the sound wave was measured using a microphone.
(103) The harmonic of a sound wave determines its frequency and pitch.
(104) The sound wave diffracts as it encounters obstacles in its path.
(105) The frequency of the sound wave is measured in cycle per second.
(106) The amplitude of a sound wave oscillates to determine its volume.
(107) I wonder what haps if we change the frequency of this sound wave.
(108) The spectral velocity of the sound wave determined its frequency.
(109) The frequency of the sound wave is measured in cycles per second.
(110) The shape information of the sound wave determined its frequency.
Sentence of sound wave
(111) The antinodes of a sound wave are where the sound is the loudest.
(112) The formants of a sound wave can be analyzed using a spectrogram.
(113) The frequency of the sound wave can oscillate at different rates.
(114) The gradient of the sound wave determined the pitch of the music.
(115) The peak amplitude of the sound wave was measured at 120 decibels.
(116) The sound wave traveled in a straight line until it hit a barrier.
(117) The decomp of a sound wave can be analyzed using Fourier analysis.
(118) The kilocycles of the sound wave can be amplified using a speaker.
(119) The antinodes of a sound wave are where the sound is the clearest.
(120) The sound wave was discretized into samples for digital recording.
Sound Wave used in a sentence
(121) The squiggly line on the sound wave graph showed a high frequency.
(122) The sound wave from the singer's voice was beautiful and powerful.
(123) The amplitude of the sound wave can oscillate at different levels.
(124) The spectral envelope of a sound wave determines its overall shape.
(125) The spectral flux of the sound wave indicated a shift in frequency.
(126) The scientist zapped the bacteria with a high-frequency sound wave.
(127) The music project requires us to test the radius of the sound wave.
(128) Theodolites are used in music to measure the angle of a sound wave.
(129) The physical makeup of a sound wave determines its pitch and volume.
(130) The kilocycles of the sound wave can be adjusted using an equalizer.
Sound Wave sentence in English
(131) The oscillograms provided a visual representation of the sound wave.
(132) The oscillograph provided a visual representation of the sound wave.
(133) The sound wave produced by the tuning fork was sinusoidal in nature.
(134) The spectral measurement of the sound wave determined its frequency.
(135) The formant bandwidth of the sound wave affects its intelligibility.
(136) The actual measurement of the frequency of the sound wave was 440 Hz.
(137) The natural scale of a sound wave determines its frequency and pitch.
(138) The waveshape of the sound wave influenced the volume of the speaker.
(139) The antinodal regions of a sound wave are where the sound is loudest.
(140) The distribution of frequencies in a sound wave determines its pitch.
(141) The residence time of a sound wave in a room can affect its acoustics.
(142) The waveform of the sound wave determined its frequency and amplitude.
(143) The spectral modulation of a sound wave can alter its perceived pitch.
(144) The waveshape of the sound wave can be visualized using a spectrogram.
(145) The flux density of the sound wave was measured using a decibel meter.
(146) The deflexion of the sound wave made it difficult to hear the speaker.
(147) The action spectrum of a sound wave determines its pitch and frequency.
(148) The measurement value of the frequency of the sound wave was 440 hertz.
(149) The wave amplitude of the sound wave increased as the music got louder.
(150) The high-order harmonics in the sound wave created a rich musical tone.
(151) The waveshape of the sound wave determined its frequency and amplitude.
(152) The antinode of the sound wave was clearly visible on the oscilloscope.
(153) The intensity of a sound wave can oscillate to produce different tones.
(154) The sinusoidal waveform of the sound wave made it pleasant to listen to.
(155) The pulse amplitude of the sound wave determined the pitch of the sound.
(156) The kilocycles of the sound wave can be equalized using audio equipment.
(157) The wave amplitude of the sound wave was measured using a decibel meter.
(158) The antinodal regions of a sound wave are where the pressure is highest.
(159) The oscillogram captured the sound wave patterns of the music recording.
(160) The wave length of a sound wave can be altered by changing the frequency.
(161) The waveshape of the sound wave determined the pitch of the musical note.
(162) The critical volume of the sound wave determines its intensity and pitch.
(163) The antinode of a sound wave is where the air pressure is at its maximum.
(164) The music students were asked to admeasure the frequency of a sound wave.
(165) The amplitude of a sound wave can oscillate to produce different volumes.
(166) The spectral analysis of a sound wave can reveal its frequency components.
(167) The rarefactions in this sound wave are responsible for its low amplitude.
(168) I used a calculating machine to determine the frequency of the sound wave.
(169) The wavenumber of the sound wave determined the pitch of the musical note.
(170) The wave number of a sound wave is directly proportional to its wavelength.
(171) The engineer will put on hold the tone frequency to analyze the sound wave.
(172) The spectrographic image depicted the sound wave's amplitude and frequency.
(173) The wavenumber of a sound wave is inversely proportional to its wavelength.
(174) The frequency of the sound wave determines the number of cycles per second.
(175) The antinodes of a sound wave are where the air molecules vibrate the most.
(176) The frequency of the sound wave would oscillate with the pitch of the note.
(177) The angle in addition to the frequency determines the pitch of a sound wave.
(178) The fundamental frequency of a sound wave is the lowest frequency component.
(179) The spectral power of the sound wave was measured to determine its amplitude.
(180) The byte in a computer's microphone is used to represent a single sound wave.
(181) The radialization of a sound wave can affect its directionality and intensity.
(182) The spectral flux of the sound wave exhibited a gradual decrease in intensity.
(183) The spectral flux of the sound wave revealed a complex frequency distribution.
(184) The wave amplitude of the sound wave was measured using specialized equipment.
(185) The wave number of the sound wave is inversely proportional to its wavelength.
(186) The subsonic frequency of the sound wave was too low for human ears to detect.
(187) The frequency of the sound wave in the ocean is measured in cycles per second.
(188) The formant frequency of the sound wave was measured using a computer program.
(189) The sound wave can be quantized into digital signals for storage and playback.
(190) The spectral decomposition of a sound wave can reveal its frequency components.
(191) The characteristic curve of this sound wave reveals its frequency and amplitude.
(192) The waveshape of the sound wave influenced the timbre of the musical instrument.
(193) The dimensional analysis of the sound wave revealed its frequency and amplitude.
(194) The frequency of a sound wave can fluctuate cyclically, creating a musical tone.
(195) The sound wave traveled through the air at a speed of 343 meters per millisecond.
(196) The vectorial representation of the sound wave shows its amplitude and frequency.
(197) The surface wave of the sound wave created a beautiful ripple effect in the water.
(198) The formant bandwidth of the sound wave can be reduced by using a low-pass filter.
(199) The frequency of the sound wave oscillated as the musician played different notes.
(200) The alternation of high and low frequencies in the sound wave determines its pitch.
(201) The measurement value of the frequency of the sound wave was determined to be 440 Hz.
(202) The asci in this array can be used to create a visual representation of a sound wave.
(203) The intensity of a sound wave decreases exponentially as it travels through a medium.
(204) The intensity of a sound is directly proportional to the amplitude of the sound wave.
(205) The residence time of a sound wave in a room affects the acoustics and reverberation.
(206) The sesquialteral frequency of the sound wave is 1.5 times the fundamental frequency.
(207) The frequency of the sound wave, measured in cycles per second, determines its pitch.
(208) The equilibrium condition of a sound wave is when the pressure variations are balanced.
(209) The frequency of the sound wave increased quadratically towards the resonant frequency.
(210) The characteristic curve of this sound wave illustrates a gradual decrease in amplitude.
(211) The formant structure of the sound wave indicated that it was produced by a human voice.
(212) The formant structure of the sound wave was altered by the presence of background noise.
(213) The frequency of a sound wave can be altered by changing the number of cycles per second.
(214) The time it takes for a sound wave to travel a short distance is measured in microseconds.
(215) The residence time of a sound wave in a room can affect its reverberation characteristics.
(216) The spectral density of the sound wave was analyzed to determine its frequency components.
(217) The engineer analyzed the partials of the sound wave to improve the acoustics of the room.
(218) The spectral flux of the sound wave exhibited a distinct peak at a specific frequency range.
(219) The equilibrium point of a sound wave is where the compression and rarefaction are balanced.
(220) The wave velocity of a sound wave can be influenced by factors such as temperature and humidity.
(221) The rarefactional sound wave caused the music to become quieter as it traveled through the room.
(222) The sound wave amplitude of the music concert was so high that it could be heard from miles away.
(223) The equilibrium point of a sound wave is when the compressions and rarefactions are evenly spaced.
(224) The energy in a sound wave is convertible into heat, which can cause objects to vibrate or resonate.
(225) The time it takes for a sound wave to travel one meter through air is approximately 3.4 microseconds.
(226) The scientist developed a sound wave generating system to study the effects of different frequencies.
(227) The couplant solution was designed to have low impedance, enabling efficient sound wave transmission.
(228) The rarefactional effect of the sound wave caused it to become fainter as it traveled through the air.
(229) The sonography technician applies a gel to the patient's skin to ensure proper sound wave transmission.
(230) The wave velocity of a sound wave can be decreased by passing it through a medium with a higher density.
(231) The antinodal points on a sound wave are where the air particles vibrate with the greatest displacement.
Sound Wave meaning
Sound wave is a term used to describe the pattern of disturbance caused by the movement of energy through a medium, such as air, water, or solids. It is an essential concept in the field of physics and plays a crucial role in various applications, including music, communication, and medical imaging. To effectively incorporate the term "sound wave" into your sentences, consider the following tips:
1. Definition and Context: Begin by providing a clear definition of sound wave to ensure your readers understand the term.
For example, "A sound wave refers to the propagation of mechanical energy through a medium in the form of oscillating pressure variations."
2. Scientific Explanation: Elaborate on the scientific principles behind sound waves, such as their nature as longitudinal waves and their ability to travel through different mediums. For instance, "Sound waves consist of compressions and rarefactions, where particles in the medium move back and forth parallel to the direction of energy transfer."
3. Examples in Everyday Life: Demonstrate how sound waves are present in various real-life scenarios. For instance, "When you hear a car horn honking, it is because the sound waves produced by the horn travel through the air and reach your ears."
4. Musical Applications: Discuss how sound waves are fundamental to the creation and perception of music. Explain concepts like pitch, frequency, and amplitude in relation to sound waves.
For example, "Musical notes are produced by sound waves with different frequencies, where higher frequencies result in higher-pitched sounds."
5. Communication and Technology: Highlight the importance of sound waves in communication systems, such as telephones, radios, and public address systems. Explain how sound waves are converted into electrical signals and transmitted over long distances. For instance, "When you make a phone call, your voice is converted into electrical signals that travel as sound waves through the phone lines."
6. Medical Imaging: Discuss the role of sound waves in medical imaging techniques like ultrasound. Explain how sound waves are used to create images of internal body structures.
For example, "Ultrasound machines use high-frequency sound waves to generate real-time images of organs, tissues, and developing fetuses."
7. Wave Properties: Explore the characteristics of sound waves, such as wavelength, speed, and reflection. Provide examples of how these properties affect the perception of sound. For instance, "The wavelength of a sound wave determines its pitch, with shorter wavelengths corresponding to higher-pitched sounds."
8. Interference and Resonance: Explain phenomena like interference and resonance, which occur when sound waves interact with each other or with objects. Provide examples to illustrate these concepts.
For example, "When two sound waves with the same frequency meet, they can interfere constructively, resulting in a louder sound."
9. Safety Considerations: Discuss the potential hazards associated with excessive exposure to loud sound waves, such as hearing loss. Provide tips on how to protect oneself from harmful noise levels. For instance, "Wearing earplugs or earmuffs in noisy environments can help reduce the impact of loud sound waves on your hearing."
10. Conclusion: Summarize the key points discussed in the article and emphasize the significance of understanding sound waves in various fields.
For example, "By comprehending the principles of sound waves, we can appreciate the beauty of music, communicate effectively, and utilize advanced technologies for medical diagnosis." Remember to adapt these tips to fit the specific context and purpose of your writing.
The word usage examples above have been gathered from various sources to reflect current and historical usage of the word Sound Wave. They do not represent the opinions of TranslateEN.com.